56from which we derive, by Theorem 1.11,
elog z+log z' = zz', elog z-log z' = z
z'Chapter 1This shows that a value of log( zz') is log z +log z', and that a value of
log( z / z') is log z - log z' for particular choices of values of log z and log z',
the results differing possibly by a multiple of 27ri.It is easy to see that if we choose the principal values of log z and log z',
we do not obtain necessarily the principal value of log(zz') or of log(z/ z').
However, we may write
Log( zz') = Log z + Log z' + 2n7riLog ( ;, ) = Log z - Log z' + 2n7ri
where n is either -1, 0 or +1, depending on whether the sum (or difference)
of the principal values of the arguments of z and z' is greater than 7r, lies
in (-?r, 1r], or is less than or equal to -?r.
Property 5 follows by noting that if z = rei^8 , then zn = rneinO, so that{logzn} = {nln r + i(nB + 2k17r)}
while
{n log z} = {n ln r + i(nB + 2k 2 n?r)}
The values in the second set coincide with those in the first only when
kzn = ki, i.e., only when ki contains n as a factor.1.16 POWERS WITH A COMPLEX BASE AND A
COMPLEX EXPONENT
Having defined powers with base. e and the natural logarithms of complex
numbers, we are in a position to define the power zw with both a complex
base (other than zero) and a complex exponent.Definition 1.10 For z f= 0 we define zw by means of the equality
The principal value of zw, denoted (p.v.)zw, is defined by
(p.v.)zw = ewLogz(1.16-1)(1.16-2)
the meaning of Logz as given in (1.15-5). For z = 0, w f= 0, we define
ow = O, while 0° is not defined.
Since log z has infinitely many values, zw as defined by (1.16-1) may have
also infinitely many values. However, when w is an integer n, the power